JPH0693692B2 - Loop-type local area network concentrator - Google Patents

Description

The present invention relates to a concentrator of a loop type local area network.

<Prior Art> FIG. 2 is an explanatory diagram showing a state in which a loop type local area network is configured using a conventional concentrator. In this example, three concentrators N _{1 to} N ₃ each having the same configuration are used, and each of the concentrators N _{1 to} N ₃ has workstations WS _{1 to} WS ₇ as terminal devices (this example). 7) are connected, and each of the workstations WS _{1 to} WS ₂ is electrically connected to the line L via the relay circuit R.
When data is transmitted from one work station, for example WS _2, to another work station, for example WS ₄ , the transmission data sent from one work station WS ₂ is used as the receiving workstation.
WS ₄ and sends adds a unique address code A _4. The transmitted transmission data is once taken in by the next workstation WS ₃ and the address code A ₄ is collated. If the address code does not match the own unique address code, the data is further transferred to the next workstation WS ₄ . If the data to the workstation WS ₄ is taken, the address code A ₄ of the destination coincides with the self-unique address code A _4, the workstation WS _4, the various data based on the input data Perform processing.

Workstations in such networks
If you want to add a new WS ₈ , add the corresponding concentrator N
Connect workstation WS ₈ to ₂ . Then,
Controller built in this concentrator N ₂ (not shown)
Then, the relay circuit R performs the set operation, and the workstation WS ₈ is connected to the line L. Further, when it is desired to leave one workstation, for example, WS ₂ , from this network, the workstation WS ₂ is pulled out from the concentrator N ₂ . Then, the above-mentioned controller resets the relay circuit R, and the workstations WS ₁ and WS _{3 on the} left and right of the relay circuit R are directly connected via the line L.

<Problems to be Solved by the Invention> By the way, in the conventional concentrators N _{1 to} N ₃ , the AC power supply AC is used as a drive source of the relay circuit R that switches the line L, and each concentrator N ₁ is used. Cable C ₁ to ~ N ₃ respectively
~ Connected via C ₃ . When such an AC power supply AC is used, the switching operation is fast and reliable, but the cables C ₁ to N ₃ are connected to the concentrators N _{1 to} N _3.
It is necessary to provide C ₃ . In particular, when the scale of the network becomes large, it is necessary to use a large number of concentrators, so that the number of cables also increases, and accordingly, there is a problem that it takes time to construct cable wiring.

To improve this, connect a capacitor that is charged by the signal from the workstation to each relay circuit, and use this capacitor as a drive source for the relay circuit, thus omitting the use of an AC power supply. Conceivable. However, when a single capacitor is connected to the relay circuit, the reset operation of the relay circuit may not be performed reliably, which may cause problems such as impairing reliability.

The present invention has been made in view of the above circumstances, and eliminates the need to use an alternating current for driving a relay circuit as in the related art, saves time and effort for wiring, and is a line connection relay. The purpose is to ensure that the operation of the circuit is always reliable.

<Means for Solving the Problems> The present invention adopts the following configurations in order to achieve the above object.

That is, the line concentrator of the present invention has a plurality of connector parts to which workstations are connected, the side connecting the workstation to the line through the connector parts, and the work corresponding to each connector part. A latching type relay circuit for switching the connection and disconnection of the station from the line, and a controller for outputting a set / reset signal to the relay circuit depending on whether or not the workstation is connected to the connector portion are provided, Moreover, the set coil and the reset coil of the relay circuit are individually connected to capacitors for charging a DC signal supplied from the workstation.

<Operation> According to the above configuration, the DC signal supplied from the workstation connected to the concentrator is charged in the capacitor, and the capacitor serves as a drive source of the relay circuit.
Therefore, external electric power is not required, and the labor for construction such as cable connection is omitted.

Further, since the capacitors are individually connected to the set coil and the reset coil of the relay circuit, both capacitors are charged within a short time by the DC signal supplied from the workstation. Therefore, even if the time from the connection of the workstation to the disconnection of the line is short, the set and reset operations are surely performed.

<Embodiment> FIG. 1 is a block diagram of a concentrator of a loop type local area network according to an embodiment of the present invention. In this figure, only the circuit portion corresponding to the connector portion for connecting one workstation is taken out and shown.

In the figure, 1 is a concentrator, and 2 is a connector part to which one workstation WS is connected and has an output terminal OUT and an input terminal IN to the workstation WS.
Reference numeral 4 denotes a latching type relay circuit provided corresponding to the connector unit 2, and disconnects the work station WS from the line L from the side connecting the work station WS to the line L via the connector unit 2. A contact portion P for switching connection to the side, a set coil Rs for setting and resetting the contact portion P, and a reset coil Rr are provided. A set capacitor Cs and a reset capacitor Cr for charging the DC signal supplied from the workstation WS are individually connected to the set coil Rs and the reset coil Rr. Reference numeral 6 denotes a controller that outputs a set / reset signal to the relay circuit 4 depending on whether or not the workstation WS is connected to the connector unit 2. This controller 6 is provided until both capacitors Cs and Cr are sufficiently charged. CR considering time
Built-in time constant circuit. Further, Ta and Tb are pulse transformers, and Ds and Dr are diodes for backflow prevention.

Next, the control operation associated with the connection and disconnection of the workstation WS in the concentrator 1 having the above configuration will be described.

Before connecting the workstation WS to the connector part 2,
The contact portion P of the relay circuit 4 is reset, and therefore, with the relay circuit 4 as the center, the workstations in the preceding stage and the workstations in the subsequent stage (both not shown) are directly connected to each other by a line L. There is.

From this state, when the workstation WS is newly connected to the connector section 2 of the concentrator 1, the DC signal supplied from the workstation WS is applied to the input terminal IN. That is, in the output signal from the workstation WS, a DC signal is superimposed on the data signal as an offset, and this DC signal is input to the input terminal of the connector unit 2.
Both capacitors Cs, Cr are supplied via IN, diodes Ds, Dr to both capacitors Cs, Cr to be charged. The DC signal is also given to the controller 6. The controller 6 outputs a low level set signal to the relay circuit 4 after a predetermined time by the CR time constant circuit has elapsed since the DC signal was input. Due to this set signal, the electric charge charged in the setting capacitor Cs is discharged through the set coil Rs and the controller 6, and in response thereto, the contact point P
Is set. As a result, the workstation WS is connected to the line L. Therefore, the data signal transmitted from the work station in the previous stage is the relay circuit 4
It is taken into the workstation WS from the contact point P of the above through the transformer Ta and the output terminal OUT. In addition, the data signal transmitted from this workstation WS is the connector unit 2
Is transmitted to the work station at the next stage via the input terminal IN, the transformer Tb, and the line L.

On the other hand, when the workstation WS is detached from the connector unit 2, the supply of the DC signal from the workstation WS is cut off. In response to this, the controller 6
A low level reset signal is output to the relay circuit 4. This reset signal causes the reset capacitor Cr to
Since the electric charge that has been charged to is discharged through the reset coil Rr and the controller 6, in response to this, the connection portion P
Is reset. This allows workstation WS
Is disconnected from the line L.

When constructing a local area network using this concentrator 1, after connecting the workstation WS to the connector section 2 and setting the relay circuit in order to confirm the operation of the relay circuit 4, the workstation WS is immediately connected. It may be removed from the connector section 2. Even in such a case, since the relay circuit 4 is reset by the charged electric charge of the reset capacitor Cr, there is no problem that the relay circuit 4 is kept in the set state, and the set and reset operations are always performed. Definitely done.

<Effects of the Invention> According to the present invention, an external power supply for driving a relay circuit is not required, so that it is possible to save time and effort such as wiring.
Moreover, the entire device can be downsized. Further, it is possible to exert an excellent effect such that a relay circuit for connecting / disconnecting the work station to / from the line can be always set and reset.

[Brief description of drawings]

FIG. 1 is a block diagram showing a part of a concentrator of a loop type local area network according to an embodiment of the present invention, and FIG. 2 is an explanation of a state in which a loop type local area network is constructed using a conventional concentrator. It is a figure. 1 ... Concentrator, 2 ... Connector part, 4 ... Relay circuit, 6 ... Controller, Rs ... Set coil, Rr ...
Reset coil, Cs, Cr ... Capacitor, WS ... Workstation.

Claims (1)

[Claims] 1. A plurality of connector parts to which workstations are connected, a side connecting the workstations to a line through the connector parts corresponding to each connector part, and the workstation from the line. A latching type relay circuit for switching the connection to the disconnecting side and a controller for outputting a set / reset signal to the relay circuit according to the presence or absence of the connection of the workstation to the connector portion are provided, respectively, and A condenser for charging a DC signal supplied from the workstation is individually connected to the set coil and the reset coil of the relay circuit.